bESC from cloned embryos do not retain transcriptomic or epigenetic memory from somatic donor cells.

In brief: Epigenetic reprogramming after mammalian somatic cell nuclear transfer is often incomplete, resulting in low efficiency of cloning. However, gene expression and histone modification analysis indicated high similarities in transcriptome and epigenomes of bovine embryonic stem cells from in vitro fertilized and somatic cell nuclear transfer embryos. Abstract: Embryonic stem cells (ESC) indefinitely maintain the pluripotent state of the blastocyst epiblast. Stem cells are invaluable for studying development and lineage commitment, and in livestock, they constitute a useful tool for genomic improvement and in vitro breeding programs. Although these cells have been recently derived from bovine blastocysts, a detailed characterization of their molecular state is lacking. Here, we apply cutting-edge technologies to analyze the transcriptomic and epigenomic landscape of bovine ESC (bESC) obtained from in vitro fertilized (IVF) and somatic cell nuclear transfer (SCNT) embryos. bESC were efficiently derived from SCNT and IVF embryos and expressed pluripotency markers while retaining genome stability. Transcriptome analysis revealed that only 46 genes were differentially expressed between IVF- and SCNT-derived bESC, which did not reflect significant deviation in cellular function. Interrogating histone 3 lysine 4 trimethylation, histone 3 lysine 9 trimethylation, and histone 3 lysine 27 trimethylation with cleavage under targets and tagmentation, we found that the epigenomes of both bESC groups were virtually indistinguishable. Minor epigenetic differences were randomly distributed throughout the genome and were not associated with differentially expressed or developmentally important genes. Finally, the categorization of genomic regions according to their combined histone mark signal demonstrated that all bESC shared the same epigenomic signatures, especially at gene promoters. Overall, we conclude that bESC derived from SCNT and IVF embryos are transcriptomically and epigenetically analogous, allowing for the production of an unlimited source of pluripotent cells from high genetic merit organisms without resorting to transgene-based techniques.

Treatment of cryopreserved bovine sperm with calcium ionophore A23187 increases in vitro embryo production.

After ejaculation, mammalian sperm undergo a series of molecular events conducive to the acquisition of fertilizing competence. These events are collectively known as capacitation and involve acrosomal responsiveness and a vigorous sperm motility called hyperactivation. When mimicked in the laboratory, capacitating bovine sperm medium contains bicarbonate, calcium, albumin and heparin, among other components. In this study, we aimed at establishing a new capacitation protocol for bovine sperm, using calcium ionophore. Similar to our findings using mouse sperm, bovine sperm treated with Ca2+ ionophore A23187 were quickly immobilized. However, these sperm initiated capacitation after ionophore removal in fresh medium without heparin, and independent of the Protein Kinase A. When A23187-treated sperm were used on in vitro fertilization (IVF) procedures without heparin, eggs showed cleavage rates similar to standardized IVF protocols using heparin containg synthetic oviduct fluid (IVF-SOF). However, when A23187 pre-treated sperm were further used for inseminating eggs in complete IVF-SOF-heparin, a significantly higher percentage of embryo development was observed, suggesting a synergism between two different signaling pathways during bovine sperm capacitation. These results have the potential to improve current protocols for bovine IVF that could also be applied in other species of commercial interest.

Review: Embryonic stem cells as tools for in vitro gamete production in livestock.

The goal of in vitro gametogenesis is to reproduce the events of sperm and oocyte development in the laboratory. Significant advances have been made in the mouse in the last decade, but evolutionary divergence from the murine developmental program has prevented the replication of these advances in large mammals. In recent years, intensive work has been done in humans, non-human primates and livestock to elucidate species-specific differences that regulate germ cell development, due to the number of potential applications. One of the most promising applications is the use of in vitro gametes to optimize the spread of elite genetics in cattle. In this context, embryonic stem cells have been posed as excellent candidates for germ cell platforms. Here, we present the most relevant advances in in vitro gametogenesis of interest to livestock science, including new types of pluripotent stem cells with potential for germline derivation, characterization of the signaling environment in the gonadal niche, and experimental systems used to reproduce different stages of germ cell development in the laboratory.

PCR detection of Tritrichomonas foetus in preputial bull fluid without prior DNA isolation.

Tritrichomonosis is a widespread, economically important venereal disease caused by Tritrichomonas foetus. The traditional diagnosis of this disease, which causes infertility and abortion in cattle, is based on the culture of the parasite. This process is time consuming, has low sensitivity, and is prone to contamination with intestinal or coprophilic trichomonadid protozoa, resulting in false positive diagnostics of T. foetus. In order to avoid the shortcomings of the traditional method, we developed a simple PCR assay based on TFR3 and TFR4 primers, which does not require parasite culturing. The sensitivity of the PCR assay resulted comparable to that of the classical method, being able to detect as few as five T. foetus parasites. In addition the method is highly specific. The analysis of preputial fluid washing samples showed that 58 out of 203 samples were positive by both, the PCR and the culture method (+/+), 9 samples were positive by PCR and negative by the traditional method (+/-) and only one sample resulted negative by PCR and negative by culture (-/+). The samples for the PCR assay can be stored for a week at 4 degrees C or 72h at room temperature. In summary, our study demonstrated that the PCR assay is an effective method for the diagnosis of T. foetus from preputial samples, and that it compares advantageously to the classical method.

Blastocele fluid from in vitro- and in vivo-produced equine embryos contains nuclear DNA.

Normal mammalian early embryonic development involves apoptosis of blastomeres as a remodeling process during differentiation, starting at the blastocyst stage. Genomic DNA has been recently detected in the blastocele fluid of human embryos and has been amplified by real-time polymerase chain reaction (PCR) to diagnose the sex of in vitro-produced human embryos. This new approach varies from conventional preimplantation genetic diagnosis in that no cells are extracted from the embryo and only the blastocele fluid is aspirated and used as a DNA sample for diagnosis. In the present work, we investigated whether the blastocele fluid of equine preimplantation embryos contains nuclear DNA and whether this DNA could be used to diagnose the sex of the embryos by conventional PCR, using specific primers that target the TSPY and AMEL equine genes. The sex of 11 of 13 in vivo-produced embryos and of four of five in vitro-produced embryos was successfully diagnosed. The PCR amplification product was analyzed using genetic sequencing reporting that the DNA present in blastocele fluid was genomic. Additionally, after polyacrylamide gel electrophoresis and silver staining, the blastocele fluid from three different embryos produced a ladder pattern characteristic of DNA fragmented during apoptosis. Therefore, the results presented in this work report that blastocele fluid from in vivo- and in vitro-produced equine embryos contains nuclear DNA which is probably originated by apoptosis of embryonic cells, and this DNA could be used to diagnose the sex of preimlpantation embryos by conventional PCR.